A Universal Approach Towards Computational Characterization of Dislocation Microstructure

TL;DR

This paper introduces a universal microstructure language that enables direct comparison and detailed analysis of dislocation microstructures across various experimental and simulation methods.

Contribution

It presents a novel, universal approach for characterizing and comparing dislocation microstructures, bridging the gap between experimental observations and simulations.

Findings

Enables direct comparison of different microstructure data

Facilitates detailed analysis of dislocation networks

Universal language applicable to diverse methods

Abstract

Dislocations - linear defects within the crystal lattice of, e.g., metals - already have been directly observed and analyzed for nearly a century. While experimental characterization methods can nowadays reconstruct three-dimensional pictures of complex dislocation networks, simulation methods are at the same time more and more able to predict the evolution of such systems in great detail. Concise methods for analyzing and comparing dislocation microstructure, however, are still lagging behind. We introduce a universal microstructure "language" which could be used for direct comparisons and detailed analysis of very different experimental and simulation methods.